Abstract

The clinical success of antibody-drug conjugates (ADCs) brentuximab vedotin and ado-trastuzumab emtansine has led to an increased effort to identify new antibody payloads and develop improved linker technologies. Most antibody payloads impart significant hydrophobicity to the ADC resulting in accelerated plasma clearance and diminished in vivo activity, particularly for conjugates with high drug to antibody ratios (DAR). Consequently, drug-linkers have been designed to minimize or mask hydrophobicity, enabling a higher DAR and improved pharmacokinetic properties, translating to enhanced in vivo potency. We recently reported on the incorporation of a discrete PEG polymer as a side chain in the β-glucuronide-monomethylauristatin E (MMAE) linker to provide homogeneous DAR 8 conjugates with decreased plasma clearance and increased antitumor activity in xenograft models relative to a non-PEGylated control. The PEG-glucuronide-MMAE lead has now been optimized by minimizing the size of the PEG side chain and incorporating a self-stabilizing maleimide to prevent payload de-conjugation in vivo. Multiple PEG-glucuronide-MMAE linker constructs were prepared with PEG size varying from 0 to 24 ethylene oxide units, and uniform DAR 8 ADCs were evaluated. PEG size had small but variable effects in vitro, with diminished activity observed in some cell lines. In contrast, a clear relationship was observed between PEG length and plasma pharmacokinetics. Longer PEG chains resulted in slower clearance, with a ‘threshold’ length beyond which clearance was not impacted. Conjugates bearing PEG of sufficient length to minimize ADC plasma clearance provided a wider therapeutic window relative to conjugates bearing shorter PEGs. Thus, sufficient masking of drug hydrophobicity is a viable strategy to provide uniform DAR 8 ADCs that preserve ADC pharmacokinetics and increase potency through higher drug loading.